• New format directly addresses DNA extraction, one of the key sources of variability in cfDNA assays
  •  Reference standard provides control throughout entire molecular assay workflow

 

Horizon Discovery Group, the world leader in the application of gene editing technologies including molecular reference standards, today announces the launch of its first HDx™ cfDNA (cell-free DNA) Reference Standard in Synthetic Plasma.
 
Since being pioneered by Horizon co-founder Professor Alberto Bardelli for the detection of KRAS mutations in serum to identify resistant populations to EGFR targeted therapy, liquid biopsy testing has emerged as one of the fastest growing areas in diagnostics, with cfDNA testing set to reach $9.0 billion by 20221. Non-invasive testing offers the possibility of earlier disease detection and more effective treatment, even more so for conditions such as lung cancer which are difficult to biopsy.
 
cfDNA based diagnostics are at a particularly high risk of error however, as these tests involve extracting a small amount of DNA from a large volume of plasma, and an assay may be required to identify as few as 50 copies of a target sequence that has already undergone DNA damage. This is further complicated by the amount of cfDNA present in a sample being highly variable patient to patient. Together, these factors can lead to considerable uncertainty regarding the amount of material available after DNA extraction, and a significant risk of over or under loading an assay.
 
It is essential therefore that clinical laboratories extract, and reliably quantify, as much cfDNA as possible. Horizon’s new Multiplex I cfDNA Reference Standard Set in Synthetic Plasma directly addresses this problem by allowing users to control for the entirety of their workflows, from sample extraction through to result reporting, interrogating the sources of variability at each step so they can address them.
 
Developed using clinically-relevant mutations, the Multiplex I cfDNA Reference Standard Set in Synthetic Plasma contains eight cancer-relevant mutations including BRAF, EGFR, KRAS, NRAS, and PIK3CA at 5%, 1%, and 0.1% allelic frequencies2. These mutations are associated with multiple forms of cancer including breast, colorectal, pancreatic and particularly lung, where one specific mutation covered in the panel, EGFR T790M, is associated with Iressa® (Gefitinib) resistance. This is an essential tool for scientists seeking to understand and control variation in molecular testing. By engineering the reference standard in plasma, full understanding of assay performance from extraction and quantification through to analysis and informatics is possible, mimicking the challenges of dealing with human material.